Perforation production tester



Nov. 3, 1953 R. O. BOYKIN, JR

PERFORATION PRODUCTION TESTER Filed March 3, 1947 lig! LIT

ROBERT O. BOYKIN JR.

Patented Nov. 3, 1953 UNITED STATES PATENT orties PERFORATION PRODUCTION TESTER Robert o. Boykin, Jr., Los Angeles, Calif.

Application March 3, 1947, Serial No'. 732,093

3 Claims.

My invention relates to means for testing well production.

Included in the objects of my invention are:

First., to provide a means for testing Well production which is. particularly adapted to the testing of wells which one or more possible productive zones occur behind the well. casing.

Second, to provide ay means of this character which is comparatively inexpensive both as to apparatus required and the time required to complete a test.

Third, to providev a means of this character whereby several potential productive. zones. may be. tested in sequence Without the production from alower zone invalidating the test ofv a higher zone.

Fourth, tov provide a means of. this. character which avoids the necessity of pumpingA wells to determine productivity.

Fifth, to provide a means of this character which is inherently dependable, and. is reliable sothat production may be. accurately gauged.Y

With the. foregoing, and. other objects in view,. reference is directed', to. the accompanying drawings in which:

Figure. 1 is an elevational view of' one form of my apparatus for testing well: production showing the apparatus in position within a well casing, the casing being shownY in section and show-- ing further and' diagrammatically a line suspension and Weight indicating means associated with the cable which supports the apparatus.

Figure 2 is a similar sectional view of: amodi@ fled form of my apparatus.

Figure' 3A is an enlarged*I fragmentary sectional I viewthrough 33 or Figure 1, showing the well liquid collector and' itsmeans of suspension from a gun perforator;

Figure 4 is a reduced-i fragmentary-I view simi-- lar to Figure 2, showing theprovision of a-iioat'.

means t'oindicateliquid level in the collector.

Figure 5 is an enlarged fragmentarysectional: viewof the collector illustrating the mannerv in which the yieldable deector' ring? engages the Walli of a surrounding. casing to'.- deect the well.' production'into the-collector.l

Figure 6 is' a. similar viewf showingrthe: position.:

which the deiiectorA ringv may assume; when thecollector is being withdrawn from the well.

My well testing apparatus is; designed` particularly for the testing'olk wellsinr.- which one or more possible productive' zones occur behind the; well casing..

Oil frequently occursin. series of superposed,

zones separated from each others, During the early life ofthe oil field, the wells may have been drilled to lower zones which were initially more productive than the higher ones. Upon depletion of the lower zone, it becomes desirable to communicate with the upper zones through the intervening well casing to get whatever production they may have. This has heretofore been accomplished quite successfully by gun perforati'ng thev well casing. opposite the oil zones. The expense of gun. perforating, however, together with the expense of testing. these upper zones has limited. this practice largely to wells with upper zones which have a high p-robability of being productive. My present apparatus and. method greatly simplifiesand expedities the procedure of investigating and determining. the production of various production zonesv which may have been traversedv by thewellcasing.

My apparatus comprises principally al collector unit- A and; a gun perfvorator unit B. Reference isY firstA directed to Figures 1 and. 3. The collector unit A includes a tubular shelill of as large diameter as is feasible for ready insertion into the casing of the well to be. tested. The lower end of the shell I is closed.- by a bottom4 2 which. is preferably conical. or tapered. 'Ilhe bottom 2 is equipped with. an externally threaded nipple which forms a,- drain port 3. The lower end of the. drain port. formsy a valve seat which closed by a ball valve d". The ball valve is encased in' a cover or cap,r 5, screw threadedto the nipple'. The cap is arranged to` support' the ball' valve so as:- to. providey passageways around the ball' valve and is provided' witha drain openingY at its lower extremity to permit discharge of the contents of thecollector unit when the cap is loosened` The. upper endf of the shell I` is provided with an.. internal'flange 6'. Clampl rings T and.` 8 lit on the ange. 6. and are secured thereto by bolts 91 The. confronting faces.. of the clamp rings 1'v and u diverge. upwardly and outwardly and clamp a correspondingly divergi'ng. collector. ring It" of y'ieldable. material' such. as synthetic rubber; The outer periphery of the collector' ring.' I0 is' slightly largerV than the casing into which` the' collector unit is designed to t' so' asto' yield'abl'y bear against the walls of the casing.

The shell Il is. equipped'y with a centrally'V l'ocatedvent tubeV l'l which may have Y loraifc'iiesv at its lower endjoined to the bottom 2' andform'= ing4 intake openings' I2.' The: ventr tube" may' be centered', relative to tleupp'er endV 0f the shell; lj by. means' of a collar I3" connected by,` spokes M to the lowermostV clamp Yringi '1.

The.' sliell I' isf preferably' centered relative to the casing by means of spring cages I5, each comprising a fixed ring and a slidable ring surrounding the shell, these rings being connected by bow springs.

l The upper extremity of the vent tube II may 'screw thread into a coupling I6, the lower end 'of which is belled to form -a skirt I1. The vent tube is provided with lateral holes I8 within the skirt I'I.`

The gun perforator unit B includes a body I, the lower end of which is reduced in diameter and threaded to receive and close the coupling I6. ,The gun perforator, per se, may be conventional, but .may be designed to re only a few shots rather than the large number commonly fired by gun perforators. As indicated by 2D, the bores of the gun units are preferably uniformly spaced and point laterally in several directions.

The upper end of the gun body I9 is connected to a cable head 2l which, in turn, is connected to a cable 22. It is preferred that the cable be the conventional conductor core cable used to support gun perforators and that the gun perforator be electrically fired. However, in view of the fact, as will be brought out hereinafter, that the u gun perforator is used above the liquid level in the well bore, the various conventional go devil gun perforator firing means may be employed.

The cable 22 passes over a measuring sheave 23 suitably associated with an indicator 24 arranged to indicate the length of cable played out and thereby indicate the depth which the gun unit and collector unit occupies in the well bore. Also associated with the measuring sheave is a weight indicator 25. Such depth and weight indicators are conventionally used with gun perforators.

Reference is now directed to Figure 2. The structure here illustrated is essentially the same as that shown in Figures 1 and 3, with the eX- ception that the gun perforator unit B is arranged below instead of above the collector unit A. To accomplish this, a vent tube 3| is substituted for the vent tube II. The vent tube 3| extends centrally through the bottom 2 of the shell I, and is provided with intake openings 32. The upper end of the vent tube 3I may be as shown in Figure 3. The coupling I6, however, is adapted for connection directly to the cable head 2I. The lower end of the vent tube 3l is connected to the upper end of the gun perforator body. cable 33 extends between the cable head 2l and the gun body I9, as indicated by dotted lines.

Reference is now directed to Figure 4. As will be brought out hereinafter, it may be desirable to know when the level of the liquid collected in the shell I approaches the upper end thereof. This may be accomplished by a float 4I surrounding the vent tube II and normally resting on a collar G2. A contact means 43 may be carried by the collar I3, which contact may be electrically connected through a cable M to wiring, not shown, contained within the body I9 of the gun perforator unit. The electrical circuit is so arranged that when the float 4l engages the contact 43, a signal may be given at the surface of the well.

My method of testing cased off formations for production employs the above-described apparatus as follows:

The gun perforator unit B and collector unit A are lowered until the gun perforator is opposite the desired zone to be tested. The gun is then red. If the construction shown in Figure 1 is employed the collector unit need not be moved after perforation. If the construction A conductor shown in Figure 2 is used, the collector unit lis lowered after the perforation is made to a point below the zone perforated by the gun unit B so as to collect the liquid production which may enter. This offers the definite advantage that an initial flow may occur before collecting the liquid. During such initial flow, debris produced by the gun perforation as well as mud or other extraneous liquid trapped behind the casing, may be discharged so that the sample later taken is free of contamination. The collector is left in place for an interval calculated to only partially fill the shell I. The length of time which the collector unit is held in place is noted. When the collector unit is raised to the surface of the well, the volume of liquid collected is measured. This may be done by noting the height of the liquid within the shell or by discharging the liquid into a suitable measuring container. By ascertaining the volume of liquid collected and the length of time required for its collection, the productivity of the well through the perforations can be accurately determined.

If the float 4I is employed, the collector unit may be held in place until the float 4I raises and operates a signal at the surface. By this method the volume collected by the collector unit is predetermined and constant. The productivity can then be determined by noting the length of time required to ll the collector unit.

It should be noted that if the normal liquid level is above the zone to be tested, the well is first bailed until the level is below this zone.

It should be observed that the flexible collector ring I0 inherently forms a relatively fluid tight connection with the walls of the casing so that no appreciable percentage of the liquid by-passes the collector unit. When the collector unit is raised, however, the collector ring I0 is sufficiently flexible to fold downwardly as shown in Figure 6 so that during the raising of the collector unit after test, accumulations on the walls of the well casing are not added to the production liquid.

Quite often such tests must be performed in wells which produce gas, often from regions below the point of test. It is therefore desirable to employ the vent tube I I to by-pass any such gaseous production originating below the collector unit. Thus, during raising or lowering of the collector unit and during the production test itself, any gas below the unit is free to by-pass, and therefore exerts no rpressure to disturb the location of the unit in the well bore.

It should be observed that the full production of a zone need not vbe tested. For example, if it. is anticipated that a particular zone might produce 1,000 4barrels per day and therefore in ex cess of the capacity of the tester, the number or size of gun perforators may be limited. Thus, if' the Zone produced say 10 barrels a day through a single small perforation, the size of which is known, the full production may be estimated with reasonable accuracy. This method of testing is. of particular advantage when it is desirable to compare low from several zones. The same size or number of gun perforations may be made opposite the several zones and the resulting flows compared.

When the collector is raised to the surface of the well, the character of the liquid produced may be determined by inspection, and test.

Many other embodiments of the invention may be resorted to without departing from the spirit of the invention.

I claim:

1. An apparatus for measuring the flow of liquids into a cased well bore said apparatus involving: a measuring container adapted t0 be lowered into the cased well bore below the region at which the liquid enters; deiiector means at the upper end of said container yieldably engaging the side walls to deect liquids into said container; and means defining a passage extending through said container for by-passing any gaseous production originating below said container.

2. An apparatus for measuring the flow of liquids into a cased well bore said apparatus involving: a measuring container adapted to be lowered by rcable into said cased well bore to a point below said region of liquid ingress; an lupwardly diverg- .ing yieldable collector ring carried at the upper end of said container to engage the Walls `of the well casing and divert liquids into said container; and means defining passageways for ow past said container of gaseous production originating below said container.

3. An apparatus for testing the productivity of wells wherein the liquid level of the well, at least during test, is below the region 0f liquid ingress, said apparatus, involving: a cable; a gun perforator and a vcontainer Suspended in tandem References Cited in the file of this patent UNITED STATES PATENTS Number Name Date 1,200,722 Gilmore Oct. 10, 1916 1,606,104 Schlueter et al Nov. 9, 1926 1,889,889 Ennis Dec. 6, 1932 1,893,162 Cranz Jan. 3, 1933 2,143,962 Stone Jan. 17, 1939 2,158,569 Bowen May 16, 1939 2,187,047 Miner Jan. 16, 1940 2,262,655 Seale Nov. 11, 1941 2,313,369 Spencer Mar. 9, 1943 2,441,894 Mennecier Mar. 18, 1948 

